Process of sampling, averaging, mixing, and storing materials in bulk.



No. 662,063. Patented Nov. 20, 1900.

T. A. emsou.

PROCESS OF SAMPLING, AVERAGING. MIXING. AND STORING MATERIALS IN BULK.

Application filed Jan. 11. 1900.) (No Model.) 3 Sheets- Sheet l.

0 Inveptor MW a I Attys.

THE cams wzrzns c0v wo'ro-umm WASHINGTON, n. c

No. 662,063. Patented Nov'. 20, I900.

T. A. EDISON. PROCESS OF SAMPLING. AVE RAGING. MIXING. AND STORING MATERIALS IN BULK.

A plication filed Jan. 11. 1900.!

3 Sheets-8heet 2.

No Model.)

Inventor m: nrmgs PEYERS co PnoTaumou Msums'rom n. a

Patented Nov. 20, I900.

T. A. zmsou. v PROCESS OF SAMPLING. AVERAGING, MIXING, AND STDR- ING MATERIALS IN BULK.

(Application filed Jan. 11. 1900.)

3 Sheets-Sheet 3.

(No Model.)

Q/ Inventor qw Attys.

Wi tn esses IINtTE THOMAS A. EDISON, OF LLEIVELLYN PARK, NEVV JERSEY.

PROCESS OF SAMPLING, AVERAGING, MIXING, AND STORING MATERIALS IN BULK.

SPECIFICATION forming part of Letters Patent N 0. 662,063. dated November 20, 1900.

- Application filed January 11. 1900 Tor/ll whom, it Wtcty concern/.-

Be it known that I, THOMAS A. EDISON, a citizen of the United States, residing at Llewellyn Park, in the county of Essex and State of New Jersey, have invented a certain new and useful Process of Sampling, Averaging, Mixing, and Storing Material in Bulk, (Case No. 1,020,) of which the following is a description.

My invention relates to various new and useful improvements in process of sampling, averaging, mixing, and storing materials in bulk; and the object of the invention is to provide a process by which ore, rock, or other material in bulk having a variable assay may be sampled and so averaged as to give in its bulk an even assay corresponding to the average assay of the samples, so that the further addition of any necessary ingredient in a subsequent operation upon the ore, rock, or other material in bulk can be so made as to produce an even product or result, the process also contemplating the storing of the averaged material and the effectivemixing thereof with such a further ingredient.

By averaging, as above used and as will be used herein, I have reference to the taking of material in bulk having throughout its contents a more or less variable assay and the redistribution of the particles of the ma terial, so that an assay made form any portion of its contents will be substantially identical with that made from any other portion ofits contents, and by mixing as used herein l have reference to the combination of two or more materials in bulk in such a way as to giveasubstantially uniform mixture throughout.

- My invention is especially designed for use in connection with the manufacture of Portland cement from silicious cement-rock and lime, generally limestone. It is well known that the silicious cement-rock used for manufacturing Portland cement by the dry process is a natural product of an exceedingly variable character as regards the various ingredienls of which it is composed-such as lime, alumina, iron, magnesia, silica, &c. and that in the same quarry the rock will vary several per cent. in its chemical constituents in a few feet. Since this rock is always deficient in lime, it is the practice in or- (No specimens.)

der to make a perfect Portland cement to mix therewith a certain percentage of limestone to obtain the proper mixture, the usual procedure being to mix several barrows of cementrock with one barrow of limestone. In effecting the mixture in this way the resulting cement varies considerably in composition, it being manifestly impracticable to assay each barrow of the cement-rock in'a large establishment. In the manufacture of such material therefore as at present carried out the mixing of the silicious cement-rock with limestone becomes more or less a matter of guesswork.

When my present invention is utilized in the specific manufacture of Portland cement having for its principal basis a natural silicious cement-rock, its essential object is to permit the making of a perfect average of cement-rock of known composition to be commercially and practically effected, so that the addition of lime will produce a mixture giving a'Portland cement of constant qualityindependent of the variations of the rock in the quarry.

A convenient apparatus for carrying out my process is illustrated in the accompanying drawings, in which Figure 1 represents diagrammatically a longitudinal section of a stock-house having a capacity for seven separate deposits, each being large enough to accommodate one days operation of the crushing plant; Fig. 2, an enlarged cross-sectional view thereof through one of the deposits, illustrating the preferable conical formation thereof, the section being taken between any two of the chutes; Fig. 3, an enlarged longitudinal sectional view through one of the deposits of the same character, the section being taken centrally through one of the chutes; Fig. 4, a diagram of the mixing apparatus; Fig. 5, a longitudinal section of a modified form of bin intended for the formation of the deposits in vertical strata; and Figs. 6 and 7, detail views looking in the direction of arrows a and b in Figs. 4 and 1, respectively.

In all of the above views corresponding parts are represented by the same numerals of reference.

'lhe stock-house l is made in any suitable form, being provided with a bottom 2, which maybe either flat or hopper-shaped. A series of partitions 3 3 divide the interior of the stock-house into several bins, each adapted to receive a deposit of the material.

4 represents an endless conveying-belt.

' suitable valve or flap 8, of any desired character, and adapted to be opened and closed by a rod 9 under the control of the operator. The character of valve illustrated generally in the drawings is of a well-known type, consisting of a flap which is carried on a pivoted rock-shaft, there being a crank on one end of the rock-shaft to which the operating-rod is connected, so that by pulling or pushing on the rod the flap may be opened or closed. Each of the spouts 5 is provided with a hopper 10 at its upper end, into which the material is deposited from the belt 4 by passing the belt over pulleys 11 11, as is common. The hopper 10 is provided with an overflow 12, by which excess of material from the feed-spout 5 will be allowed to fall upon the belt 4 and to be carried on to the next feedspout. The hopper 10 is preferably provided with a flap 13, by means of which material may be deflected immediately through the overflow 12 and be prevented from entering any one of the feed-spouts 5. The lower sides of each bin are inclined, shown, and at the bottom said sides are formed into a series of hoppers 14, as shown clearly in Fig. 3, said hoppers being arranged one in front of the other, and placed within one side of each of said hoppers is a roller-feed 15, the spout 15 of which allows material from within the hopper to be directed to a feed-belt 16, by means of which the material from any one of the deposits may be drawn off and deposited through a lateral chute 16 (see Fig. 7) onto an endless mixing-belt 17,which extends,preferably, parallel with the feed-belt 4 at the top of the stock-house. For the sake of clearness in Fig. 1 I illustrate the mixing-belt 17 as being carried on a plane below the belt 4; but the preferred location of this mixing-belt with respect to the belt 4 is shown in Fig. 2, both belts being maintained in the same plane. The mixing-belt 17 passes over a plurality of pulleys corresponding to pulleys 11 11 and deposits material into one or more hoppers 18, arranged above each of the bins and comm nnicating with the spouts 5. The hoppers 18 are the same in construction and operation as the hoppers 10, and said hoppers l0 and 18 both feed into the samefeed-spout, as will be seen. Mounted within each of the hoppers 14, at the sides of the roller-feeds 15, are other roller-feeds l9, delivering into spouts 20, corresponding to the spouts 15". Extending beneath all of the spouts 20 is an endless belt 21, by means of which the averaged material may be carried to a suitable mixing apparatus,as shown in Fig. 4. In Fig. 1,for the purpose of clearness, I show the belts 16 and 21 as being extended on different planes; but preferably these belts are arranged side by side, as shown in Fig. 2. The said mixing apparatus comprises two bins or receptacles 22 23, one for containing cement-rock and the other for containing limestone. These bins are of great capacitysay one hundred tons each. A movable feed-spout 24 is pivoted above the two bins, whereby material from the belt 21 may be deposited into one or the other of said bins. Each of the bins 22 and 23 is provided with a roller-feed 25 therein, and located beneath said roller-feeds are smaller receptacles 26 and 27, carried on platform'scales 28 and 29 of any desired construction. From the receptacles 26 and 27 the material may be drawn off by means of spouts 30 and deposited into a mixing apparatus 31 of any suitable type. The flow of material from the receptacles 26 and 27 may be controlled in any suitable way. I illustrate diagrammatically a we1l-known form of,rotary mixer for this purpose, said mixer being provided with ribs extending longitudinally thereof to thoroughly agitate the material. Located beneath the mixing apparatus 31 is a hopper 32, into which the mixed material may be deposited, said hopper being provided with a roller-feed 33 for feeding the mixed material therefrom onto an endless con veyingbelt 34, leading to a suitable storage stockhouse for the mixed material.

In order to carry the material from the crushing plant, I prefer to employ a conveying-belt 35, between which and the conveyor 4 may be located a sampling apparatus 36 of any suitable type, arranged to automatically remove from the material falling from the belt asmallsampleatregularintervalsoftime for instance, one pound each minute. These samples from the sampling-machine are conveyed by means of a chute 37 to a sample'receptacle 38.

I prefer to utilize an apparatus of the kind above described for the carrying out of my improved process, said apparatus being provided above each bin with a single inclined feed-spout, whereby, as will be explained, the material will be caused to accumulatein each bin in the form of a conical pile in stratified layers. It will be understood, however, that the material may be accumulated in other forms of depositsfor example, in vertical layers-by dividing each bin into a number of vertical compartments by means of partitions 39, as shown in Fig. 5. With such a modification the feed-spout 5 is provided with two branches 40 and 41, extending over the several compartments of each bin, as shown. With this modification the several compartments of each bin may be proportioned, so as to be of substantially the same capacity, as shown. With this modification each branch IIO 40 and 41 of the feed-spout will be provided with valved openings 7, as is the case with a single feed-spout, and the said openings will be controlled in the same way by means of valves and operating-rods, as I have already described. The bottom of each com partment will be provided with two roller-feeds l and 19 therein, so that material can be drawn off simultaneously from all of the compartments and deposited upon the belt 16 or 21, the case may require. In the description of the operation which is carried outin the apparatus I will first have reference to the formation of the material in conical piles by the employment of a single feed-spout for each bin.

In the representation of the stock-house shown in Fig. l I have indicated two full cones A and B, representing limestone; a cone 0 of limestone, which has been partly removed; a full cone D of cement-rock; a portion of a cone E of cement-rock, which is being. redistributed, averaged, and deposited at F, and a cone Gof cement-rock, which is being formed by direct deposit from the crushing plant. It will be of course understood that this arrangement and number of cones can be varied to suit any condition of actual operation.

With an apparatus of the character explained and in the manufacture of Portland cement I carry on my process in the following way: Material from the crushing plant after being passed through a drier, if neces sary, will be conveyed by the belt 35 and deposited on the belt at, samples thereof being taken automatically by means of the sampling-machine 36 and deposited in the receptacle 38. The deflecting-flaps 13 of the feedspouts for the piles B, E, and D are closed, so that the cement-rock will be carried by the belt 4 and will be deposited in the feed-spout 5 for the pile G. The valves 8 of that feedspout are all closed by the attendant, and material will therefore fiowout of the lower end of the feed-spout and accumulate in a pile essentially conical in shape, as shown in Fig. When this pile reaches the open end of the feed-spout, material will immediatelyaccumulate therein and will overflow through the spout 12. As soon as this is observed by the attendant the valve 8 for the lowermost opening is opened, whereupon the material accumulated in the feed-spout will immediately flow out therefrom and material will begin to accumulate in the form of a partial cone, as shown, which will abut against the cone formed by the material flowing out of the lowereud of the spout 5. When this partial cone is formed, material will once again accumulate in the feed-spout, giving notice tothe attendant by overflowing, whereupon the valve for the second opening will be operated and a new partial cone will be formed, these operations being repeated until the entire cone is produced of a number of stratified or overlapping partial cones, as

shown very clearly in Fig. Each of these cones will preferablybe of sufficient capacity to represent at least a days operation of the crushing plant, so that ample time ill be afforded the chemist in charge to make a proper assay. Olwiously the samples which have accumulated in the receptacle 38 will if intimately mixed together give an assay correctly representative of that of the cone as a whole, and this assay is made in any suitable way from such samples. Assuming the cone in question to have been formed in one day, the averaging of the same will be preferably effected on the succeeding day by allowing the material therefrom to be drawn off through the roller-feeds 15 and deposited on the conveying-belt 16. Irepreseut in dotted lines in Fig. 3 the contents of each of the cones or piles which will be drawn off therefrom by each of the roller-feeds, from which it will be obvious that in every case the material withdrawn by one of the roller-feeds will have been accu m nlated onto the original cone at'diverging times. Thus if it be assumed that each of the five partial cones forming the entire pile were formed in two hours the operation of all the roller-feeds will result in material being drawn off from the pile, which will be representative of the run of the crushing plant during substantially its entire time, the first. roller-feed to the left drawing ofi": material deposited during the first two hours, then material deposited during the second two hours; the next roller-feed first drawing oif material deposited during the first two hours, then material deposited during the second two hours, then material deposited during the third two hours, and finally material deposited during the fourth two hours; the third roller-feed first drawing off material depos-.

ited during the first two hours, then drawing off material deposited during the second two hours, then drawing off material deposited during the third two hours, then drawing off material deposited during the fourth two hours, and finally drawing off material deposited during the fifth two hours; the next roller-feed first drawing off material deposited during the second two hours, then drawing off material deposited during the third two hours, then drawing off material deposited during the fourth two hours, and finally drawing off material deposited during the fifth two hours; the next roller-feed first drawing off material deposited during the third two hours, then drawing off material deposited during the fourth two hours, and then drawing ofif material deposited during the fifth two hours, and the sixth roller-feed to the right drawing otf material deposited during the third, fourth, and fifth two hours. The material thus drawn off will be deposited on the belt 16 in six layers, the bottom layer representing portions of the material deposited in the bin during the first and second periods of two hours, the next layer representing the lirst-,second,third,and fourth two hours, the next layer representing the first,

second, third, fourth, and fifth periods, the next layer representing the second, third, fourth, and fifth periods, the next layer representing the third, fourth, and fifth periods, the next layer representing the third, fourth, and fifth periods. Although by drawing off material in this way a rough approximation of an average will be secured, it is desirable that the operation should be carried on to a further, state of perfection, and therefore the material drawn off through the roller-feeds 15 onto the conveying-belt 16 is deposited on the mixing-belt 17, being further mixed in the transfer from one belt to the other and is returned through the hopper 18 of one of the feed-spoutsas, for instance, that for the pile Fso as to be re-formed in a new cone. I illustrate this transfer of material, an averaging thereof to be taking place, from the cone E to the cone F. While a pile of cement-rock is illustrated as being formed at G in the first instance and a transfer from the cement-rock pile E is illustrated as taking place with the redeposit thereofat F with the obvious averaging which will be secured by such transfer, the belt 21 is employed for carrying off from the stock-house material from any one of the piles into which it has been redeposited in an averaged condition. Thus I show the pile (J of limestone as being carried off by the belt 21, While operating the roller-feeds 19 for such pile.

Instead of depositingthe material in each bin in the form ofa pile or cone, as explained, so that it will accumulate in inclined strata, representing different periods of operation, the material may be deposited in each bin in any other forn1-as, for example, in the vertical compartments shown in the modified arrangement illustrated in Fig. 5. Thus the material representing the first period of time of the operation of the crushing plant may be deposited in the first compartment at the left, and when said compartment is full notification will be offered by overflow, whereupon the valve for the first opening 7 of the leg 40 will be opened to fill the second com; artment, and so on. In removing the material from such a bin through all of the roller-feeds it will be observed that the material as it falls upon the belt 16 from each of the vertical compartments will be representative of the several periods of operation of the crushing plant in which the bin in question was being supplied with the material. The same general result is secured in one case as in the other, and any other arrangement of bins and forms of deposits can be utilized by which the result desired may be obtained. From the stockhouse the material which has been thus averaged is carried by the belt 21 and deposited in the bin or receptacle 22 or 23, this operation being effected so as to keep said bins properly supplied with material. Assuming the bin 22 to contain cement-rock in a perfectly-averaged condition from a'known de posit, the assay of which has been determined by the chemist by making an assay of the samples, as explained, the roller-feed 25 for said bin is operated and material is Withdrawn therefrom to fill the receptacle 26, and the weight of this material is determined by the scales 28. The chemist knowing the assay of the cement-rock in the receptacle 26, it is only necessary therefore to operate the roller-feed 25 for the bin 23 and to accumulate in the receptacle 27 a sufiicieut amount of limestone as to result in a mixture of which a Portland cement of the desired quality can be obtained. When a sufiicient amount of limestone has been accumulated in the receptacle 27, the roller-feed 25 for the bin 23 is stopped and both materials are deposited through the hoppers 30 into the mixer 31, where an intimate mixing of the two materials is effected, after which the mixed materials are allowed to drop out of the mixer into the hopper 32, from which they are deposited f'rom the roller-feed 33 onto the conveying-belt 34 and are carried to a suitable stock-house ready for further operation.

Ordinarily with natural silicious cementrock of the average proportions in the manufacture of Portland cement it will be a convenient operation to accumulate in the stockhouse the cement-rock in three deposits during runs of three successive days to effect the averaging of such deposits on the days succeeding their original formation to run the crushing plant on the limestone for one day to form a deposit thereof, and on the first day of the run on the cement-rock to effect the averaging of a deposit of limestone originally accumulated. In the withdrawal of the material off from the stock-house by means of the belt 21 it is only necessary to keep the storage-bins 22 and 23 properly supplied with material,care being of course taken not to carry upon the conveying-belt cement-rock and limestone at the same time.

While it is desirable that samples of the material going to the formation of each deposit should be taken out during the formation thereof in order that an average assay may be made whichwill correspond to that of the deposit after it has been redistributed and averaged, as explained, whereby after such averaging thematerial may be immediately withdrawn from the stock-house, yetit will be understood that the material may be deposited in the first instance in the stockhouse, as explained, then redistributed and averaged therein, and that from the deposit which has been thus averaged a portion may be taken as a sample which may be then assayed, which assay will be correctly representative of that of the deposit as a whole. Obviously the use of a sampling device effects a saving of time, since the material may be drawn off from the redistributed deposit immediately after the said cone is formed.

Having now described my invention, what I claim as new, and desire to secure by Letters Patent, is as follows:

IIO

1. The process of averaging material in bulk, which consists in forming the material in a deposit composed of a series of layers, in simultaneously drawing off material from each of the layers of which the deposit is formed, in redistributing the material in a deposit and in tin-ally withdrawing the material therefrom, substantially as set forth.

2. The process of averaging material in bulk, which consists in forming the material in a deposit composed of a series of layers, in simultaneously drawing oif material from each of the layers of which the deposit is formed, in redistributing the mateiial in a corresponding deposit composed in its turn of layers, and in withdrawing from the redeposit material simultaneously from each of the layers of which it is formed, substantially as set forth.

The process of averaging and mixing materials in the manufacture of Portland cement, which consists in accumulating the cement-rock in a deposit in bulk, in securing samples of the cement-rock at intervals of time during its deposit, in making an average assay of said samples, in averaging the deposit of cement-rock, and in mixing the ocmen t-rock with the proper proportion of limestone, sul'istantially as set forth.

4. The process of averaging and mixing materials in the manufacture of Portland cement, which consists in depositing cementrot-k in bulk in aseries of layers, in securing samples of the rock at intervals during the deposit thereof, in making an average assay of said samples, in drawing off the cementrock simultaneously from each of the layers of which the deposit is formed, and in mixing the cement-rock with the proper proportion of limstone, substantially as set forth.

5. The process of averaging and mixing materials in the manufacture of Port-land cement, which consists in depositing cementrock in bulk in a series of layers, in withdrawing the material sim ultaneouslyfrom the several layers forming said deposit, in redistri but-ing the cement-rock and accumulating it in a new deposit, in drawing off the material from the new deposit, and in mixing therewith the proper proportion of limestone, sub stantially as set forth.

6. The process of averagingandmixingmaterials in the manufacture of Portland cement, which consists in depositing cementrock in bulk in a series of layers, in withdrawing the material simultaneously from the several layers forming said deposit, in redistributing the cement-rock andaccumulating it in a new deposit composed of a series of layers, in withdrawing the material from the new deposit simultaneously frotn each of the layers of which it is formed, and in adding the proper proportion of limestone thereto, substantially set forth.

7'. The process of averagingand mixing materials in the manufacture of Portland cement, which consists in accumulating the cemerit-rock in layers, in securing samples of the rock at. intervals during the de osit thereof, in making an average assay of said samples, in withdrawing the material from the deposit simultaneously from all portions of which it is composed, in completing the averaging oi the material so withdrawn by redistributing it in a new deposit, in withdrawing the material from the new deposit so formed, and in adding thereto a proportion of limestone determined by the assay, substantially as set forth.

8. The process of averaging and mixing materials in the manufacture of Portland cement, which consists in accumulating the cement-rock in layers, in securing samples of the rock at intervals during the deposit thereof, in making an average assay of said samples, in withdrawing the material from the deposit simultaneously from all the layers of which it is composed, in completing the averaging of the material so withdrawn by redistributing it in the form of a new deposit composed of a series of layers, in withdrawing the material from the new deposit simultaneously from each of the layers, and in adding to the material so withdrawn a proportion of limestone determined from the assay, substantially as set forth.

9. The process of making Portland cement, which consists in accumulating cement-rock in a deposit, in redistributing the cementrock from said deposit and accumulating it in a new deposit in an averaged condition, in accumulating limestone in a deposit, in redistributing the limestone deposit in a new deposit in an averaged condition, in determining the assay of the cement-rock deposit, in weighing a proportion of the cement-rock, in obtaining a proportion of the limestone deposit determined by the assay of the cementrock, and in mixing the proportions of cement-rock and limestone so obtained, substantially as set forthv 10. The process of making Portland cement, which consists in depositing cement-rock in bulk in a series of layers, in drawing off the cement-rock simultaneously from each of the layers of which the deposit is formed, in redistributing the cenient-rock so drawn off and accumulating it in a new deposit in a series of layers, in making an assay of the new deposit, in depositing limestone in bulk in a series of layers, in drawing ofi the limestone simultaneously from each of the layers of which the deposit is formed, in redistributing the limestone so drawn off and accumulating it in a new deposit in the form of a series of layers, in drawing off from the cementa-ock deposita certain proportion thereof, in drawing off from the limestone deposit a proportion determined by the assay of the cementrock, and finally in mixing the proportions of cement-rock and limestone so drawn off, substantially as set forth.

ll. The process of averaging material in bulk, which consists in forming the material in a conical pile composed of a series of inclined layers or partial cones, and in simul taneously drawing off material from each of the layers of which the conical pile is formed, substantially as set forth.

12. The. process of averaging material in bulk, which consists in forming the material in a conical pile composed of a series of inclined layers or partial cones, in simultaneously drawing oif material from each of the layers of which the conical pile is formed, in redepositing the material in a conical pile and in finally withdrawing the material th erefrom, substantially as set forth.

13. The process of averaging material in bulk, which consists in forming the material in a conical pile composed of a series of inclined layers or partial cones, in simultaneously drawing off material from each of the layers of which the conical pile is formed, in redepositing the material in a conical pile composed in its turn of inclined layers or partial cones. and in withdrawing from the redeposited pile material simultaneously from each of the layers of which it is formed, sub stantially as set forth.

1%. The process of averaging and mixing materials in the manufacture of Portland cement, which consists in depositing cementrock in bulk in a series of partial cones orincliued layers to form a conical pile, in securing samples of the rock at intervals during the deposit thereof, in making an average assay of said samples, in drawing off the ocment-rock simultaneously from each of the partial cones of which the pile is formed, and in mixing the cement-rock with the proper proportion of limestone, substantially as set forth.

15. The process of averaging and mixing materials in the manufacture of Portland cement, which consists in depositing cementrock in bulk in a series of partial cones or inclined layers to form a conical pile, in withdrawing the material simultaneously from the several partial cones forming said pile, in redistrilmting the cement-rock and depositing it in a new pile, in drawing otf the material from the new pile, and in mixing therewith the proper proportion of limestone, substantially as set forth.

16. The process of averaging and mixing materials in the manufacture of Portland cement,which consists in depositing cementrock in bulk in a series of partial cones or inclined layers to form a conical pile, in withdrawing the material simultaneously from the several partial cones forming said pile, in redistributing the cement-rock and depositing it in a new pile composed of a series of partial cones, in withdrawing the material from the new pile simultaneously from each of the partial cones of which itis formed, and in addingthe proper proportion of limestone thereto, substantially as set forth.

17. The process of averaging and mixing materials in the manufacture of Portland cement, which consists 'in accumulating the cement-rock in the form of a conical pile composed of inclined layers or partial cones, in securing samples of the rock at intervals during the deposit thereof, in making an average a say of said samples, in withdrawing the material from the pile simultaneously from all portions of which it is composed, in completmg the averaging of the material so withdrawn by retlepositing it in a new pile, 1n withdrawing the material from the new pile so formed, and in adding thereto a proportion of limestone determined by the assay, substantially as set forth.

18. The process of averaging and mixing materials in the manufacture of Portland cement, which consists in accumulating the cement-rockin the form of a conical pile composed of inclined layers or partial cones, in securing samples of the rock at intervals during the deposit thereof, in making an average assay of said samples, in withdrawing the material frotn the pile simultaneously from all portions of which it is composed, in completing the averaging of the material so with drawn by depositing it in the form of a conical pile composed of a series of inclined layers or partial cones, in withdrawing the ma terial from the new pile simultaneously from each of the partial cones, and in adding to the material so withdrawn a proportion of limestone determined from the assay, substantially as set forth.

This specification signed and witnessed this 9th day of January, .1900.

THOMAS A. EDISON.

Witnesses:

J. F. RANDOLPH, EDWIN E. HAGERTY. 

